Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids
An interrupted microchannel heat sink (IMCHS) using nanofluids as working fluids is analyzed numerically to increase the heat transfer rate. The rectangular IMCHS is designed with length and width of 10mm and 0.057mm respectively while optimum cut section number, n c=3. The three dimensional governi...
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my.uniten.dspace-295132023-12-28T14:30:18Z Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids Tokit E.M. Mohammed H.A. Yusoff M.Z. 35756670600 15837504600 7003976733 Heat transfer enhancement Interrupted microchannel heat sink Nanofluid Optimization Finite volume method Heat sinks High pressure effects Mixed convection Nanoparticles Optimization Particle size Reynolds number Transport properties Volume fraction Governing equations Heat Transfer enhancement Heat transfer rate Micro channel heat sinks Nanofluids Nanoparticle diameter Nu number Parametric study Particle diameters Thermal Performance Working fluid Nanofluidics An interrupted microchannel heat sink (IMCHS) using nanofluids as working fluids is analyzed numerically to increase the heat transfer rate. The rectangular IMCHS is designed with length and width of 10mm and 0.057mm respectively while optimum cut section number, n c=3. The three dimensional governing equations (continuity, momentum and energy) were solved using finite volume method (FVM). Parametric study of thermal performance between pure water-cooled and nanofluid-cooled IMCHS are evaluated for particle diameter in the range of, 30nm to 60nm, volume fraction in the range of, 1% to 4%,nanofluid type of Al 2O 3, CuO, and SiO 2 at Reynolds number range of 140 to 1034 are examined. The effects of the transport properties, nanofluid type, nanoparticle volume fraction and particle diameter are investigated on the IMCHS performance. It is inferred that the Nu number for IMCHS is higher than the conventional MCHS with a slight increase of the pressure drop. It is found that highest thermal augmentation is predicted for Al 2O 3, followed by CuO, and finally for SiO 2 in terms of Nu nf/Nu pw in the IMCHS. The Nu number increased with the increase of nanoparticle volume fraction and with the decrease of nanoparticle diameter. � 2012 Elsevier Ltd. Final 2023-12-28T06:30:18Z 2023-12-28T06:30:18Z 2012 Article 10.1016/j.icheatmasstransfer.2012.10.013 2-s2.0-84869201995 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84869201995&doi=10.1016%2fj.icheatmasstransfer.2012.10.013&partnerID=40&md5=7c67a54bba26de03b802c16185041670 https://irepository.uniten.edu.my/handle/123456789/29513 39 10 1595 1604 Scopus |
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Heat transfer enhancement Interrupted microchannel heat sink Nanofluid Optimization Finite volume method Heat sinks High pressure effects Mixed convection Nanoparticles Optimization Particle size Reynolds number Transport properties Volume fraction Governing equations Heat Transfer enhancement Heat transfer rate Micro channel heat sinks Nanofluids Nanoparticle diameter Nu number Parametric study Particle diameters Thermal Performance Working fluid Nanofluidics |
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Heat transfer enhancement Interrupted microchannel heat sink Nanofluid Optimization Finite volume method Heat sinks High pressure effects Mixed convection Nanoparticles Optimization Particle size Reynolds number Transport properties Volume fraction Governing equations Heat Transfer enhancement Heat transfer rate Micro channel heat sinks Nanofluids Nanoparticle diameter Nu number Parametric study Particle diameters Thermal Performance Working fluid Nanofluidics Tokit E.M. Mohammed H.A. Yusoff M.Z. Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids |
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An interrupted microchannel heat sink (IMCHS) using nanofluids as working fluids is analyzed numerically to increase the heat transfer rate. The rectangular IMCHS is designed with length and width of 10mm and 0.057mm respectively while optimum cut section number, n c=3. The three dimensional governing equations (continuity, momentum and energy) were solved using finite volume method (FVM). Parametric study of thermal performance between pure water-cooled and nanofluid-cooled IMCHS are evaluated for particle diameter in the range of, 30nm to 60nm, volume fraction in the range of, 1% to 4%,nanofluid type of Al 2O 3, CuO, and SiO 2 at Reynolds number range of 140 to 1034 are examined. The effects of the transport properties, nanofluid type, nanoparticle volume fraction and particle diameter are investigated on the IMCHS performance. It is inferred that the Nu number for IMCHS is higher than the conventional MCHS with a slight increase of the pressure drop. It is found that highest thermal augmentation is predicted for Al 2O 3, followed by CuO, and finally for SiO 2 in terms of Nu nf/Nu pw in the IMCHS. The Nu number increased with the increase of nanoparticle volume fraction and with the decrease of nanoparticle diameter. � 2012 Elsevier Ltd. |
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35756670600 Tokit E.M. Mohammed H.A. Yusoff M.Z. |
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Tokit E.M. Mohammed H.A. Yusoff M.Z. |
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Tokit E.M. |
title |
Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids |
title_short |
Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids |
title_full |
Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids |
title_fullStr |
Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids |
title_full_unstemmed |
Thermal performance of optimized interrupted microchannel heat sink (IMCHS) using nanofluids |
title_sort |
thermal performance of optimized interrupted microchannel heat sink (imchs) using nanofluids |
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2023 |
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1806426217308487680 |
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